Successful development of a shed-microspore culture protocol for doubled haploid production in Indonesian hot pepper (Capsicum annuum L.).

Various systems of anther and microspore cultures were studied to establish an efficient doubled haploid production method for Indonesian hot pepper (Capsicum annuum L.). A shed-microspore culture protocol was developed which outperformed all the previously reported methods of haploid production in pepper. The critical factors of the protocol are: selection of flower buds with more than 50% late unicellular microspores, a 1 day 4 degrees C pretreatment of the buds, followed by culture of the anthers in double-layer medium system for 1 week at 9 degrees C and thereafter at 28 degrees C in continuous darkness. The medium contained Nitsch components and 2% maltose, with 1% activated charcoal in the solid under layer and 2.5 muM zeatin and 5 muM indole-3-acetic acid in the liquid upper layer. All the ten genotypes of hot pepper tested, responded to this protocol. The best genotypes produced four to seven plants per original flower bud. This protocol can be used as a potential tool for producing doubled haploid plants for hot pepper breeding.

Analysis of microspore-specific promoters in transgenic tobacco.

In order to modify the early stages of pollen development in a transgenic context microspore-specific promoters are required. We tested two putatively microspore-specific promoters, the Bp4 promoter from rapeseed and the NTM19 promoter from tobacco. Expression of the gus and barnase reporter genes under the control of these two promoters was studied in transgenic tobacco. Contrary to expectations, the Bp4 promoter became active only after the first pollen mitosis, and not in the microspores. The NTM19 promoter turned out to be highly microspore-specific and directed very high levels of gus expression to the unicellular microspores. The NTM19-barnase transgene caused cell-autonomous death at the mid-unicellular microspore stage, whereas Bp4-barnase induced cell ablation of early to mid-bicellular pollen. Both promoter-barnase transgenes did not affect the sporophyte and were inherited through the female germline. These results show that both the NTM19 and Bp4 promoters are expressed only in the male germline, and that the NTM19 promoter is an excellent tool to direct high levels of transgene expression exclusively to the microspores. This may have important biotechnological applications.

Temperature controls both gametophytic and sporophytic development in microspore cultures of Brassica napus.

Temperature controls the developmental fate of isolated Brassica napus microspores in vitro. Culture at 32.5°C leads to sporophytic development and the formation of embryos. Here we show that culture at 17.5°C leads to gametophytic development, and the formation of pollen-like structures at high frequencies (up to 80% after 7 days in culture). Early stages of both developmental pathways are observed in culture at 25.0°C, and embryos are produced at low frequencies (0.7%) at that temperature. Culturing B. napus microspores at 32.5°C versus 17.5°C brings the switch from gametophytic to sporophytic development under simple experimental control and provides a convenient tool for investigating the cellular and molecular mechanisms controlling this developmental switch.

Organogenesis versus embryogenesis from long-term suspension cultures of cucumber (Cucumis sativus L.).

Suspension cultures were initiated from leaf explant-derived callus of cucumber,Cucumis sativus cv. Hokus, and maintained under two different conditions; (I) continuously in medium with 5 µM 2,4-D + 5 µM BA, and (II) alternately three cultures in medium containing 5 µM NAA + 5 µM BA and one culture in 5 µM 2,4-D + 5 µM BA. After plating on solid medium with 0.5 µM KIN + 0.1 µM IAA, suspension aggregates from long-term culture in medium with 2,4-D developed into callus, and subsequently formed somatic embryos. These embryos, however, hardly developed into plants. They showed growth arrest and several structural abnormalities. In contrast, organogenesis took place when suspension aggregates from NAA containing medium were plated on solid medium with 0.5 µM KIN + 0.1 µM IAA. Numerous adventitious buds were regenerated, which quite normally developed into plants. Sucrose at low concentration of 1% improved plant formation. On the average thirty complete plants were obtained from each ml of suspension. It is discussed why adventitious buds develop into plants so well, whereas somatic embryos are prone to growth arrest and abnormal development.